H.H. Kim, Y.J. Song, S.Y. Lee, H. Joo, N. Jang, D. Jung, Y.S. Park, S.O. Park, K.M. Lee, S. Joo, S.W. Lee, S. Nam, K. Kim
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引用次数: 11
摘要
铁电随机存取存储器(FRAM)具有非易失性、高耐用性、快速读写时间和低功耗等优点,被认为是一种未来的存储器件。最近,采用1T1C电容-位线(COB)电池结构和三重金属化技术开发了4mb FRAM (S.Y. Lee等,VLSI Symp.)。技术,挖掘。,第141页,1999年)。然而,目前的4mb FRAM器件由于其低密度、低成本和大单元尺寸因素,不能令人满意地用作独立应用的主要存储器件。因此,迫切需要开发超过32 Mb的高密度FRAM器件,以应用于独立存储设备。在本文中,我们首次报道了一个高度可制造的32 Mb FRAM的开发,该FRAM由300 nm电容器堆栈技术在COB电池结构中实现,双封装阻挡层(EBL)方案,最佳层间介电(ILD)和金属间介电(IMD)技术,以及一种新的公共细胞通孔方案。
Novel integration technologies for highly manufacturable 32 Mb FRAM
Ferroelectric random access memory (FRAM) has been considered as a future memory device due to its ideal properties such as non-volatility, high endurance, fast write/read time and low power consumption. Recently, a 4 Mb FRAM was developed using 1T1C capacitor-on-bit-line (COB) cell structure and triple metallization (S.Y. Lee et al, VLSI Symp. Tech. Dig., p. 141, 1999). However, the current 4 Mb FRAM device cannot satisfactorily be used as a major memory device for stand-alone application due to its low density, cost ineffectiveness, and large cell size factor. Therefore, it is strongly desired to develop high density FRAM devices beyond 32 Mb for application to stand-alone memory devices. In this paper, we report for the first time development of a highly manufacturable 32 Mb FRAM, achieved by 300 nm capacitor stack technology in a COB cell structure, a double encapsulated barrier layer (EBL) scheme, an optimal inter-layer dielectric (ILD) and intermetallic dielectric (IMD) technology, and a novel common cell-via scheme.
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